无线多媒体网络中一种基于测量网络状态的动态呼叫接纳控制算法

提出了一种无线多媒体网络中基于测量网络状态的动态呼叫接纳控制算法.它区分了实时和非实时业务,在网络带宽资源不足时可通过降低非实时业务带宽确保实时业务呼叫连接的可靠性;还可根据当前网络状况调整预留带宽大小,使小区实时业务切换呼叫掉线率低于设定的门限值.大量仿真结果显示该算法具有低实时业务切换呼叫掉线率和与固定预留方案相当的带宽利用率,而只以略高的新呼叫阻塞率为代价,适合各种不同概率发生时实际应用的情况.     

一种支持宽带无线多媒体网络QoS的动态呼叫接纳策略

在无线网络中,小区微型化的趋势使得呼叫切换发生的频率越来越高,迫切需要一种有效的呼叫接纳控制策略,对有限的无线带宽资源进行分配,以保证切换时的QoS,同时使带宽利用率最高。传统的预留带宽策略(GC,guard channel scheme)由于其固有的静态特征而不能适应流量模式的变化。最近,人们发现采用动态的随机控制策略能适应流量模式的变化,而且能使精度和稳定性大大提高。但将这种策略应用于多业务环境依然十分困难,挑战来自于多类呼叫的QoS要求、流量模式、切换率的多样性和宽带条件下的实时可计算性。在文[3]中,我们建立了一个随机控制模型,可以在宽带条件下实时地进行多业务接纳控制,但由于没有考虑复杂的边界条件,控制精度受到影响。本文,我们在考虑边界条件的情况下,求解该随机问题,并采用一种有效的数值方法,使计算复杂度大大降低,保证了计算的实时性。最后得到的多业务动态接纳控制策略具有较高的控制精度和良好的可计算性。仿真结果显示该策略能稳定地满足多业务QoS对呼叫中断概率的严格限制,同时又能保证信道的高利用率。     

基于负载均衡的多跳中继网络接纳控制算法

针对多跳中继无线网络提出一种基于负载均衡策略的呼叫接纳控制算法。在新的用户业务到达时,小区内服务基站根据当前小区负载情况,同时检测邻居小区的负载情况,判断是否将位于小区边缘的固定中继站切换到邻居小区,以减轻当前小区的负载,接纳更多的用户。仿真分析表明,基于负载均衡的接纳控制算法可以有效控制热点小区的业务量,降低新进用户阻塞率和切换用户掉话率。     

OFDMA系统中的多业务接入控制算法

提出一种针对分析正交频分多址接入(OFDMA)系统的改进多业务接入控制算法。OFDMA系统为用户提供一定数量的子载波进行传输,通过压缩原信道带宽或传输速率,降低原信道上的业务服务质量,从而提高小区内可使用的信道数量。仿真结果表明,与传统信道预留算法相比,该算法可提高信道资源利用率,降低目标小区的切换呼叫阻塞率和新呼叫阻塞率。     

基于马尔科夫链的联合呼叫接入控制算法

异构网络的接入策略与网络资源管理效率紧密相关;同时,网络复杂性与网络资源竞争性直接影响到用户服务质量。针对异构网络接入控制存在的切换掉话率和呼叫阻塞率高、资源利用率低等问题,提出了基于马尔科夫链的联合呼叫接入控制算法。接入控制算法为切换呼叫业务、实时业务动态地预留了一定的带宽资源,根据不同业务设置带宽降级因子来决定是否释放带宽;同时,根据用户偏好和不同业务的QoS要求,构建了呼叫接入控制效用函数,利用马尔科夫链进行了建模分析。仿真表明,算法提高了网络资源利用率,降低了系统复杂度,满足了各类业务的QoS要求。     

异构分层无线网络中基于业务和逗留时间的动态流量均衡算法

在异构分层无线网络中使用有效的流量均衡技术,可以给更多的移动用户提供服务。现有的流量均衡算法主要针对同种无线网络,因而不能直接用于异构无线网络。本文提出了一种适用于异构无线网络的基于业务和逗留时间的动态流量均衡算法,该算法首先根据移动模型计算移动用户在小区内的逗留时间,然后基于小区呼叫到达率和重叠覆盖小区的流量状态来确定一个周期内转移的非实时性呼叫数量,最后依据逗留时间门限值将重负载小区中满足条件的呼叫转移到轻负载的重叠覆盖小区中。为降低切换呼叫掉线率,还对异构网间的呼叫切换策略做了改进。仿真实验结果表明．本算法在新呼叫阻寒率和切换呼叫掉线率等性能指标上比传统方法有显著提高．     

部分共享型综合业务网流量拥塞控制策略

为控制流量拥塞,提出以在线的各类On-Off型实时可变比特率业务连接的峰值带宽和预期的分组丢失率门限为依据的部分共享型呼叫接纳控制策略。给出呼叫损失概率和分组丢失率的计算方法,分析这些服务质量指标与该策略中可动态调整的控制参数之间的关系,对相关结论给予数学证明或数值验证。     

IEEE802.16中基于自适应信道预留的呼叫接入策略

呼叫接入控制（CAC）在宽带无线接入（BWA）服务质量（QoS）中起着非常重要的作用。对无线城域网中IEEE802.16复杂的QoS定义,该文提出了一种在IEEE802.16中基于自适应资源预留的呼叫接入控制策略（AR-CAC）。该策略根据UGS负载和信道利用率为其自适应预留信道,同时考虑了IEEE802.16业务的带宽特性。仿真结果表明,该策略在硬切换呼叫切换失败概率不变的情况下降低了高优先级服务的呼叫阻塞率,同时增大了系统的吞吐量。     

支持多重业务的地面电视双向方案呼叫接入控制算法

对于支持多重业务的地面电视系统双向方案,呼叫接入控制影响着用户的QoS和系统的性能.本文基于对已有的呼叫接入控制算法的研究以及地面电视双向方案的业务特点,将缓冲队列策略与适应性带宽分配策略相结合,提出一种适用于多重业务的地面电视系统双向方案的多级降级呼叫接入控制算法.通过MATLAB仿真验证,该算法能够有效降低上述系统的CBP和HDP.     

综合业务系统中切换呼叫损失概率的计算方法

准确、快速地得出通信系统中的呼叫损失概率是实现实时呼叫接入控制的前提。该文提出一种新的无线综合业务系统信道预留策略,基于该策略给出在给定系统小区的信道数、预留信道数、新呼叫与切换呼叫负荷以及接入控制策略前提下,能快速、准确地计算新呼叫及切换呼叫的呼叫损失概率的方法。仿真结果与算法得到的结果是相符的。     

Implementation of call admission control scheme in next generation mobile communication networks using particle swarm optimization and fuzzy logic systems

In the present and next generation wireless networks, cellular system remains the major method of telecommunication infrastructure. Since the characteristic of the resource constraint, call admission control is required to address the limited resource problem in wireless network. The call dropping probability and call blocking probability are the major performance metrics for quality of service (QoS) in wireless network. Many call admission control mechanisms have been proposed in the literature to decrease connection dropping probability for handoffs and new call blocking probability in cellular communications. In this paper, we proposed an adaptive call admission control and bandwidth reservation scheme using fuzzy logic control concept to reduce the forced termination probability of multimedia handoffs. Meanwhile, we adopt particle swarm optimization (PSO) technique to adjust the parameters of the membership functions in the proposed fuzzy logic systems. The simulation results show that the proposed scheme can achieve satisfactory performance when performance metrics are measured in terms of the forced termination probability for the handoffs, the call blocking probability for the new connections and bandwidth utilization.     

Joint call and packet QoS in cellular packet networks

This paper proposes a novel call admission control scheme capable of providing a combination of call and packet level quality of service requirements in cellular packet networks. Specifically, we propose a distributed call admission control scheme called PFG, which maximizes the wireless channel utilization subject to a predetermined bound on the call dropping and packet loss probabilities for variable-bit-rate traffic in a packet-switched wireless cellular network. We show that in wireless packet networks, the undesired event of dropping an ongoing call can be completely eliminated without sacrificing the bandwidth utilization. Extensive simulation results confirm that our scheme satisfies the hard constraint on call dropping and packet loss probabilities while maintaining a high bandwidth utilization.     

Service Adaptability in Multimedia Wireless Networks

Next-generation wireless communication systems aim at supporting wireless multimedia services with different quality-of-service (QoS) and bandwidth requirements. Therefore, effective management of the limited radio resources is important to enhance the network performance. In this paper, we propose a QoS adaptive multimedia service framework for controlling the traffic in multimedia wireless networks (MWN) that enhances the current methods used in cellular environments. The proposed framework is designed to take advantage of the adaptive bandwidth allocation (ABA) algorithm with new calls in order to enhance the system utilization and blocking probability of new calls. The performance of our framework is compared to existing framework in the literature. Simulation results show that our QoS adaptive multimedia service framework outperforms the existing framework in terms of new call blocking probability, handoff call dropping probability, and bandwidth utilization.      

Mobility-based predictive call admission control and bandwidth reservation in wireless cellular networks

This paper presents call admission control and bandwidth reservation schemes in wireless cellular networks that have been developed based on assumptions more realistic than existing proposals. In order to guarantee the handoff dropping probability, we propose to statistically predict user mobility based on the mobility history of users. Our mobility prediction scheme is motivated by computational learning theory, which has shown that prediction is synonymous with data compression. We derive our mobility prediction scheme from data compression techniques that are both theoretically optimal and good in practice. In order to utilize resource more efficiently, we predict not only the cell to which the mobile will handoff but also when the handoff will occur. Based on the mobility prediction, bandwidth is reserved to guarantee some target handoff dropping probability. We also adaptively control the admission threshold to achieve a better balance between guaranteeing handoff dropping probability and maximizing resource utilization. Simulation results show that the proposed schemes meet our design goals and outperform the static-reservation and cell-reservation schemes.     

An adaptive scheme for admission control in ATM networks

This paper presents a real time front-end admission control scheme for ATM networks. A call management scheme which uses the burstiness associated with traffic sources in a heterogeneous ATM environment to effect dynamic assignment of bandwidth is presented. In the proposed scheme, call acceptance is based on an on-line evaluation of the upper bound on cell loss probability which is derived from the estimated distribution of the number of calls arriving. Using this scheme, the negotiated quality of service will be assured when there is no estimation error. The control mechanism is effective when the number of calls is large, and tolerates loose bandwidth enforcement and loose policing control. The proposed approach is very effective in the connection oriented transport of ATM networks where the decision to admit new traffic is based on the a priori knowledge of the state of the route taken by the traffic.     

User mobility oriented predictive call admission control and resource reservation for next-generation mobile networks

This paper addresses the problem of resource reservation (RR) and call admission control (CAC) in wireless mobile networks. A new user mobility oriented predictive scheme called PCAC-RR is proposed for call admission control and resource reservation. The main goal is to reduce the call dropping probability and the call blocking probability, and to maximize the bandwidth utilization. By analyzing the previous movements of the mobile users, we generate local and global mobility profiles for mobile users, which are utilized effectively in the prediction of the future path of a mobile user. Extensive simulation is used to study the performance of the proposed technique and to compare its performance with other two techniques: FR-CAT2 and PR-CAT4. Simulation results show that the proposed scheme has a significantly better performance compared to the other two schemes.     

Dynamic slot assignment protocol for QoS support on TDMA-based mobile networks

An efficient bandwidth allocation scheme in wireless networks should not only guarantee successful data transmission without collisions but also enhance the channel spatial reuse to maximize the system throughput. The design of high-performance wireless Local Area Network (LAN) technologies making use of TDMA/FDD MAC (Time Division Multiple Access/Frequency Division Duplex - Medium Access Control) is a very active area of research and development. Several protocols have been proposed in the literature as TDMA-based bandwidth allocation schemes. However, they do not have a convenient generic parameters or suitable frame repartition for dynamic adjustment. In this work, we undertake the design and performance evaluation of a QoS (Quality of Service)-aware scheme built on top of the underlying signaling and bandwidth allocation mechanisms provided by most wireless LANs standards. The main contribution of this study is the new guarantee-based dynamic adjustment algorithm used in MAC level to provide the required QoS for all traffic types in wireless medium especially Wireless ATM (Asynchronous Transfer Mode). Performance evaluation of this approach consists of improving the bandwidth utilization, supporting different QoS requirements and reducing call reject probability and packet latency.     

Optimization for adaptive bandwidth reservation in wireless multimedia networks

In future wireless multimedia networks, user mobility management for seamless connection regarding realtime multimedia applications is one of the most important problems. In this paper we propose an opportunity-cost concept-based approach for adaptive bandwidth reservation with admission control for handover calls utilizing network traffic information. Excessive reservation guarantees low blocking probability of handover calls at the cost of high blocking probability of new calls. According to our survey, however, it may degrade bandwidth utilization while no prioritization for handover admissions degrades quality of service (QoS) for ongoing calls. We consider both QoS assurance and bandwidth utilization in order to optimize the amount of bandwidth to reserve for handover admissions. We believe that our scheme could be utilized as a guideline for cost-effective radio resource allocation in mobile multimedia networks.